1. Chapter 6 Memory

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5. Stage Model of Memory

6. Three Stages of Memory Three memory stores that differ in function, capacity, and duration Long-term memory Working or Short-term Memory Sensory Input Sensory Memory Attention Encoding Retrieval Maintenance Rehearsal

7. Sensory Memory Function—holds information long enough to be processed for basic physical characteristics Capacity—large can hold many items at once Duration—very brief retention of images.3 sec for visual info 2 sec for auditory info Sensory Input Sensory Memory

8. Sensory Memory Divided into two types: iconic memory–visual information echoic memory– auditory information George Sperling studied iconic memory Sensory Input Sensory Memory

9. Sensory Memory Sensory memory forms automatically, without attention or interpretation Attention is needed to transfer information to working memory Sensory Input Sensory Memory

10. Sensory Memory Visual sensory memory—brief memory of an image or icon; also called iconic memory Auditory sensory memory—brief memory of a sound or echo; also called echoic memory Auditory sensory memories may last a bit longer than visual sensory memories

11. Short Term or Working Memory Working or Short-term Memory Sensory Input Sensory Memory Attention

12. Short-Term Memory Function—conscious processing of information where information is actively worked on Capacity—limited (holds 7+/-2 items) Duration—brief storage (about 30 seconds) Working or Short-term Memory Sensory Input Sensory Memory Attention

13. Maintenance Rehearsal Mental or verbal repetition of information allows information to remain in working memory longer than the usual 30 seconds. Working or Short-term Memory Sensory Input Sensory Memory Attention Maintenance Rehearsal

15. Chunking Grouping small bits of information into larger units of information expands working memory load. Which is easier to remember? 4 8 3 7 9 2 5 1 6

16. Long-Term Memory Once information passes from sensory to working memory, it can be encoded into long-term memory Long-term memory Working or Short-term Memory Sensory Input Sensory Memory Attention Encoding Retrieval Maintenance Rehearsal

17. Long-Term Memory Function—organizes and stores information more passive form of storage than working memory Unlimited capacity Duration—thought by some to be permanent Long-term memory Working or Short-term Memory Sensory Input Sensory Memory Attention Encoding Retrieval Maintenance Rehearsal

18. Long-Term Memory Encoding—process that controls movement from working to long-term memory store Retrieval—process that controls flow of information from long-term to working memory store Long-term memory Working or Short-term Memory Sensory Input Sensory Memory Attention Encoding Retrieval Maintenance Rehearsal

19. Automatic vs. Effortful Encoding Automatic processing Unconscious encoding of information Examples: What did you eat for lunch today? Was the last time you studied during the day or night? You know the meanings of these very words you are reading. Are you actively trying to process the definition of the words?

20. Automatic vs. Effortful Encoding Effortful processing Requires attention and conscious effort Examples: Memorizing your notes for your upcoming Introduction to psychology exams Repeating a phone number in your head until you can write it down

21. Types of Long Term Memory Explicit memory—memory with awareness; information can be consciously recollected; also called declarative memory Implicit memory—memory without awareness; memory that affects behavior but cannot consciously be recalled; also called nondeclarative memory

23. Explicit Memory Declarative or conscious memory Memory consciously recalled or declared Can use explicit memory to directly respond to a question Two subtypes of explicit memory

24. Explicit Memory Episodic information—information about events or “episodes” Semantic information—information about facts, general knowledge, school work

25. Episodic Memory Memory tied to your own personal experiences Examples: What month is your birthday? Do you like to eat caramel apples? Q: Why are these explicit memories? A: Because you can actively declare your answers to these questions

26. Semantic Memory Memory not tied to personal events General facts and definitions about the world Examples: How many tires on a car? What is a cloud? What color is a banana?

27. Semantic Memory Q: Why are these explicit memories? A: Because you can actively declare your answers Important note: Though you may have personal experience with these items, your ability to answer does NOT depend on tying the item to your past i.e., Do not have to recall the time last week when you ate a banana to say that bananas are yellow

28. Implicit Memory Nondeclarative memory Influences your thoughts or behavior but does not enter consciousness Three subtypes—We will look only at one (procedural)

29. Procedural Memory Memory that enables you to perform specific learned skills or habitual responses Examples: Riding a bike Using the shift stick while driving Tying your shoe laces Q: Why are these procedural memories implicit? A: Don’t have to consciously remember the steps involved in these actions to perform them Try to explain to someone how to tie a shoelace

30. How are memories organized? Hierarchical organization Associations

31. Related items clustered together to form categories Related categories clustered to form higher- order categories Remember list items better if list presented in categories poorer recall if presented randomly Even if list items are random, people still organize info in some logical pattern Hierarchical Organization

33. Semantic Network Model Mental links between concepts common properties provide basis for mental link Shorter path between two concepts = stronger association in memory Activation of a concept starts decremental spread of activity to nearby concepts

34. Semantic Network Model Red Fire House Cherry Apple Rose Pear Ambulance Fire Engine Truck Bus Car Flower Violet Hot Pot Stove Pan Pie

35. Review of Long-term Memory Long-term memory Working or Short-term Memory Sensory Input Sensory Memory Attention Encoding Retrieval Maintenance Rehearsal Retrieval transfers info from LTM to STM Forgetting—inability to retrieve previously available information Why do people forget?

36. Why do we forget? Forgetting can occur at any memory stage Retrieval from long-term memory Depending on interference, retrieval cues, moods, and motives, some things get retrieved, some don’t Long-term storage Some items are altered or lost Short-term memory A few items are both noticed and encoded Sensory memory The senses momentarily register amazing detail

37. Forgetting as retrieval failure Retrieval—process of accessing stored information Sometimes info IS encoded into LTM, but we can’t retrieve it. Retrieval failure leads to forgetting Retrieval X Encoding Short-term memory Long-term memory

38. Tip of the tongue phenomenon TOT—involves the sensation of knowing that specific information is stored in long-term memory but being unable to retrieve it Can’t retrieve info that you absolutely know is stored in your LTM

39. Measures of Retrieval Recall—test of LTM that involves retrieving memories without cues, also termed free recall Cued recall—test of LTM that involves remembering an item of information in response to a retrieval cue Recognition—test of LTM that involves identifying correct information from a series of possible choices Serial position effect—tendency to remember items at the beginning and end of a list better than items in the middle

40. Encoding Specificity When conditions of retrieval are similar to conditions of encoding, retrieval is more likely to be successful. You are more likely to remember things if the conditions under which you recall them are similar to the conditions under which you learned them.

41. Encoding Specificity Context effects—environmental cues to recall State dependent retrieval—physical, internal factors Mood congruence—factors related to mood or emotions

42. Memory Distortion Memory can be distorted as people try to fit new info into existing schemas. Giving misleading information after an event causes subjects to unknowingly distort their memories to incorporate the new misleading information.

43. Loftus Experiment Subjects shown video of an accident between two cars Some subjects asked: How fast were the cars going when they smashed into each other? Others asked: How fast were the cars going when they hit each other? Accident Leading question: “About how fast were the cars going when they smashed into each other?” Memory construction

44. Loftus Results Word Used in Question Average Speed Estimate smashed collided bumped hit contacted 41 m.p.h. 39 m.p.h. 38 m.p.h. 34 m.p.h. 32 m.p.h.

45. Eyewitness Testimony Scripts—type of schema Mental organization of events in time Example of a classroom script: Come into class, sit down, talk to friends, bell rings, instructor begins to speak, take notes, bell rings again, leave class, etc.

46. Eyewitness Testimony Recall not an exact replica of original events Recall a construction built and rebuilt from various sources Often fit memories into existing beliefs or schemas Schema—mental representation of an object, scene, or event Example: schema of a countryside may include green grass, hills, farms, a barn, cows, etc.

47. The Forgetting Curve Hermann Ebbinghaus first began to study forgetting using nonsense syllables Nonsense syllables are three letter combinations that look like words but are meaningless (ROH, KUF)

48. Forgetting Theories Encoding failure Interference theories Motivated forgetting Decay

49. Forgetting as encoding failure Info never encoded into LTM Encoding X Long-term memory Encoding failure leads to forgetting Short-term memory

50. Which is the real penny?

51. Answer

52. Encoding Failures Even though you’ve seen thousands of pennies, you’ve probably never looked at one closely to encode specific features.

53. Interference Theories “Memories interfering with memories” Forgetting NOT caused by mere passage of time Caused by one memory competing with or replacing another memory Two types of interference

54. Two Types of Interference Types of Interference Retroactive Interference Proactive Interference

55. Retroactive Interference When a NEW memory interferes with remembering OLD information Example: When new phone number interferes with ability to remember old phone number

56. French 101 Mid-term exam Retroactive Interference Example: Learning a new language interferes with ability to remember old language F- Study French papier livreplume école Study Spanish papel libropluma escuela retroactive interference

57. Proactive Interference Opposite of retroactive interference When an OLD memory interferes with remembering NEW information Example: Memories of where you parked your car on campus the past week interferes with ability find car today

58. Motivated Forgetting Undesired memory is held back form awareness Suppression—conscious forgetting Repression—unconscious forgetting (Freudian)

59. Decay Theories Memories fade away or decay gradually if unused Time plays critical role Ability to retrieve info declines with time after original encoding Average percentage of information retained 20 mins 1 hr 8 hrs 24 hrs 2 days 6 days 31 days Interval between original learning of nonsense syllables and memory test 100%

60. Decay Theories Biology-based theory When new memory formed, it creates a memory trace, a change in brain structure or chemistry. If unused, normal brain metabolic processes erode memory trace. Theory not widely favored today

61. Biological Basis of Memory Karl Lashley searched for a localized memory trace or engram. Found that maze- learning in rats was distributed throughout the brain.

62. Biological Basis of Memory Richard Thompson found that memory for simple classically conditioned responses was localized (in the cerebellum).

63. New Memories in a Snail Aplysia—a sea snail was used to study how memories can change neurons

64. Biological Basis of Memory Amnesia—severe memory loss Retrograde amnesia—inability to remember past episodic information; common after head injury; need for consolidation Anterograde amnesia—inability to form new memories; related to hippocampus damage